Novel p-phenylstilbyl heterocyclic and naphthyl-vinylphenylene heterocyclic optical brighteners

ABSTRACT

THE PRESENT INVENTION RELATES TO NEW COMPOUNDS OF THE FORMULA   (4-(DELTA-),B-PHENYL)-CH=CH-GAMMA   IN WHICH B REPRESENTS A HYDROGEN ATOM OR A METHYL GROUP, $ REPRESENTS A DIPHENYL OR 1-NAPHTHYL OR 2-NAPHTHYL RESIDUE AND $ DENOTES A RESIDUE OF THE SERIES WHERE (I) D REPRESENTS HYDROGEN OR PHENYL, E AND F REPRESENT PHENYL, STILLBENYL, P-PHENYLSTILLBENYL OR BENZOSTILBENYL, AND FURTHERMORE Y2 REPRESENTS A BRIDGE MEMBER -O-, -NH- OR -N(ALKYL)-, WHERE (II) U5 DENOTES HYDROGEN, A STRYRL RESIDUE OR A P-PHENYLSTYRYL RESIDUE, AND WHERE (III) TERMINAL PHENYL OR NAPHTHYL RESIDUES MAY CONTAIN ALKYL, HALOGEN OR ALKOXY GROUPS. THESE NEW COMPOUNDS REPRESENT VALUABLE OPTICAL BRIGHTENING AGENTS.   -C&lt;(-Y2-(1,2-PHENYLENE)-N=), 4-D,5-(C6H5-)OXAZOL-2-YL,   2-(4-U5-PHENYL),4,5-DI(C6H5-)IMIDAZOL-1-YL, AND   4-F,5-E-4H-1,2,4-TRIAZOL-3-YL     2H-BENZOTRIAZOL-2-YL, 2H-NAPHTHO(1,2-D)TRIAZOL-2-YL,

; US. Cl. 260-240 CA United States Patent Qffice a (Patented Dec. 25, 1973 ABSTRACT OF THE DISCLOSURE The present invention relates to new compounds of the formula in Which b represents a hydrogen atom or a methyl group, 7 represents a diphenyl or l-naphthyl or 2-naphthyl residue and 6 denotes a residue of the series .where (I) d represents hydrogen or phenyl, e and 1 represent phenyl, stilbenyl, pphenylstilbenyl or benzostilbenyl, and furthermore Y represents a bridge member --O- ,NH-- or -N(alkyl)-, where (11) U denotes hydrogen, a styryl residue or a p-phenylstyryl residue, and where (III) terminal phenyl or naphthyl residues may contain alkyl, halogen or alkoxy groups.

These new compounds represent valuable optical brighten ing agents.

CROSS-REFERENCE TO RELATED APPLICATION This application is a continuation-in-part of copend ing application Ser. No. 588,318 filed Oct. 21, 1966, now abandoned and refiled as streamline continuation Ser. No. 142,388 on May 11, 1971, now US. Pat. 3,732,221 issued May 8, 1973. r

The present invention relates to a new class of stilbene derivatives which are valuable optical brightening agents. The new compounds correspond to the general formula in which b represents a hydrogen atom or a methyl group, 7 represents a diphenyl, l-naphthyl or Z-naphthyl residue, and 6 denotes a residue of the series Where (I) d represents hydrogen or phenyl, n and f represent phenyl, stilbenyl, p-phenylstilbenyl or benzostilbenyl, and furthermore Y represents a bridge member --O, -NH- or -N(a1kyl), wherein (11) U deunotes hydrogen, a styryl residue or a p-phenylstyryl residue, and wherein (III) terminal phenyl or naphthyl residues may contain 1 to 3 alkyl groups, 1 to 2 halogen atoms or an alkoxy group.

Within the above class of compounds the following subgroups of compounds are of special practical importance:

(I) Compounds of the formula in which the symbol Q represents a Z-oxazole or benzthiazole residue and X and X denote branched alkyl groups, or one of the substituents X and X denote branched alkyl groups, or one of the substituents X and X, denotes a phenyl group or two adjacent substituents X and X denote a condensed-on carbocyclic ring.

(II) Compound of formula in which R" denotes a benzene or naphthalene ring condensed with the triazole ring in the manner indicated by the valency lines, R denotes a benzene residue bonded to the triazole ring and the -CH= group in the 1,4-

position and R denotes a diphenyl or naphthyl group.

(III) Oxazole compounds of formula 'in which G denotes hydrogen, an alkyl group having 1 to" 4 carbon atoms, a'phenyl-group,-"a"phenylalkylgroup group or may, together with an adjacent residue G2 and in which Q and Q represent a member "selected from with 1 to 4 carbon atoms inthe alkyl group, halogen or a sulphonamide group, G represents hydrogen or an alkyl (VIII) Compounds of the formula in which U and U denote a member selected from the group consisting of a hydrogen atom, a styryl residue, a p-phenyl-styryl residue and a benzostyryl residue, but at least one of the U-residues differs from hydrogen.

In these formulae possible alkyl groups in principle also include long chain alkyl groups, but in practice it is mostly alkyl groups containing up to about 8 carbon atoms, preferably 1 to 4 carbon atoms, and especially branched-chain alkyl groups, which require consideration.

Though again in the case of alkoxy groups higher members, that is to say those containing 4 or more carbon atoms, as well as polyalkyleneoxy groups, are possible, the predominant practical significance resides in alkoxy groups containing 1 to 4 carbon atoms. Amongst the halogens quoted, chlorine is of especial interest.

The compounds of General Formula 1, and subordinated formulae are valuable optical brighteners (provided they do not contain any chromophoric groups).

From the point of view of use as optical brighteners for the most varied organic materials in which optical brighteners are desirable/the following types of compounds are of preferred interest:

(a) Compounds of formula the benzene ring to which these G-residues are attached, 5 form a naphthalene ring, g represents hydrogen or methyl and I denotes a diphenyl, l-naphthyl or 2-naphthyl residue, wherein terminal phenyl or naphthyl residues may additionally contain 1 to 3 alkyl groups, 1 to 2 halogen 10 atoms or an alkoxy group. 1 I

.(IV) Benzthiazole compounds of formula c--orr=oH-K, 5

in which K represents a diphenyl residue or a l-naphthyl or 2-naphthyl residue.

(V) Compounds of formula (6) L';CH=CH N L's-CH=CH JG-L. 2 5

in which L' denotes a diphenyl or naphthyl residue and LC; hydrogen, a styryl residue or a p-phenylstyryl residue.

(VI) Compounds of formula I @Q- I a).

in which U U and U denote a hydrogen atom, a styryl residue or a phenylstyryl residue and at least one symbol U differs from hydrogen.

(VII) Compounds of the formula the group consisting of a hydrogen atom, astyryl residue, a p-phenyl-styryl residue and a benzostyryl residue, ,Q denotes a member selected from the group consisting of a phenylresidue, a diphenyl residue and a naphthyl residue and terminal phenyl or naphthyl residues may further carry halogen atoms, alkoxy groups'or alkyl groups' (preferably containing up to 4 carbon atoms).

in which A represents hydrogen, an alkyl group having 1 to 18 carbon atoms, an aryl residue, especially a phenyl residue, an aralkyl residue (especially a phenyl-C -al=kyl residue) or a halogen atom and s denotes an integer from 1 to 3, preferably 1, and X represents hydrogen, alkyl or halogen.

(b) Compounds of formula inwhich A represents hydrogen, an alkyl group having 1 to 18 carbon atoms, an aryl residue, especially a phenyl residue, an aralkyl residueespecially a phenyl-C -a1kyl residue or a halogen atom and s denotes an integer from 1 to 3, preferably 1, and X represents hydrogen, alkyl or halogen.

(c) Compounds of formula (e) Compounds of the formula wherein B represents a member selected from the group consisting of p-chlorophenyl, 4-diphenylyl, l-naphthyl, 2- naphthyl, m-chlorophenyl, 3,4-methylenedioxy-phenyl.

(f) Compounds of the formula wherein G represents 4-(benzoxazolyl-2)-phenyl or 4- (n-aphthoxazolyl-2)-phenyl, wherein the 4-(benzozazolyl- 2)phenyl may he substituted in position 5 by phenyl, methyl, isopropylphenyl, tert.butyl or N-octyl-sulphonamido group, and in position 6 by phenyl or methyl.

(g) Compounds of the formula J1 CH=CH-Jg wherein I is a member selected from the group consisting of S-phenyl-benzoxazolyl-(Z) 6-phenyl-benzoxazolyl-(2), 5 tert.butyl-benzoxazolyl (2), benzoxazolyl (2) and naphthoxazolyl (2), I is a member selected from the group consisting of l-nap'hthyl and Z-naphthyl and J and 1. each represents a member selected from the group consisting of hydrogen and methyl.

(h) The compounds of the formula '6 has two adjacent ring members in common with two adjacent ringmembersof R in which R denotes a car- I bocyclic or heterocyclic rings system of aromatic character which contains 6 ring members, and which optionally is condensed with further aromatic or hydroaromatic ring systems, and in which (b) the methyl group shown in the formula is in a p-position to the. bond to R is reacted with a Schilf base in the presence of a strongly basic alkali compound, with the reaction medium to be used being dimethylformamide and being practically anhydrous, except in the case of the use of an alkali hydroxide as the strongly basic alkali compound in which case the alakil hydroxide may have a water content of up to 25%.

Within the framework of this process one type of reaction according to Formula 18 is of importance.

The reaction of anils of aldehydes of aromatic character, in the manner described above with compounds of formula CHa in which formula (a) G, B and D each denotes a ring atom of a S-membered or 6-membered ring system of aromatic character, with at least one of the symbols G, B and D representing a nitrogen atom, and where D may instead of nitrogen also denote a carbon atoms and G as well as B may represent carbon, nitrogen, oxygen or sulphur atoms in the arrangement of ring systems which are in themselves known, (b) E represents the ring member supplementation to give a S-membered or 6-membered ring system of aromatic character, containing carbon, nitrogen, oxygen or sulphur atoms in the arrangement of ring systems which are in themselves known, and in which (c) the rings which are formed conjointly with the symbol B may contain further substituents, which like the substituent X do not contain any atoms which may be replaced by alkali, especially hydrogen atoms, and p represents the numbers 0 or 1 and q the numbers 0, 1, 2 or 3.

The aforementioned substituents may be of any desired @Q- gQ-(WQ- Q-Q III-N The compounds according to this invention and defined above are generally prepared by the process for manufacture of heterocyclic compounds containing ethylene double bonds as described in US. patent application Ser. No. 588,318, filed Oct. 21, 1966.

This process is characterized by reacting a compound of formula RQ-Rr-CH:

in which R represents a heterocyclic ring system of aromatic character which (a) contains one to two 5- membered or 6-membered heterocyclic rings with one to three ring nitrogen atoms, any other hetero atom in the ring being no more than one sulfur or oxygen atom and such heterocyclic rings with a condensed-on benzene or naphthalene ring, (b) is free of hydrogen atoms which (1) are bonded to ring nitrogen atoms and (2) which are replaceable by alkali metal, and (c) is bonded to a ring member of R by means of a ring member or aliphatic, cycloaliphatic araliphatic or aromatic nature or may represent functional substituents (e.g. canboxylic acid ester groups and the like) as long as they fulfill the I preceding condition.

Here R and R have the significance given above, AN== represents an amine residue and =CH--R rep- 7 resents an aldehyde residue, in which R denotes a residue of an aldehyde of aromatic character.

The heterocyclic ring system R may consist of one or more rings. At the same time it is a prerequisite in all cases that this ring system R should contain a hetero-cyclic ring, having to 6 ring members and containing ring nitrogen atoms, this ring in turn being bonded to R and in fact either (a) in such a way that one ring atom of this heterocyclic ring is bonded to a ring atom of R by means of one bond, or (b) that this heterocyclic ring has two, in each case adjacent, ring atoms in common with R that is to say that it forms a condensed ring system. The statement that the ring system R may consist of one or more rings, denotes that for example (a) R consists only of one heterocyclic ring having 5 to 6 ring members and containing ring nitrogen atoms, or (b) a heterocyclic compound as defined under (a) contains further carbocyclic rings (especially 6-rings) condensed to it (preferably a benzene or naphthalene ring), or (c) a heterocyclic compound as defined under (a) contains further aromatic rings of carbocyclic or heterocyclic nature bonded via a single valence (that is to say not condensed), or (d) a heterocyclic compound as defined under (a) is condensed with further heterocyclic rings, in which case hetero-atoms may also be common to two rings, or (e) combinations of the abovementioned variante with one another.

One of the reagents to be used for the process of the invention, namely the compound according to Formula 18 is capable of very broad variation within the framework of the definition given above.

Suitable starting materials for preparing the compounds according to this invention are compounds of formula in which R denotes a heterocyclic ring system which contains at least one S-membered to 6-membered heterocyclic ring with a ring member which is directly bonded to R and a nitrogen atom which is exclusively bonded into the ring, and R represents a benzene residue or naphthalene residue bonded to R and to the H C-group in the 1,4- position. Here the ring system R preferably consists of a S-membered to G-membered heterocyclic ring and a benzene or naphthalene ring condensed with this ring, with the rings referred to again being able to have further substituents, as may be the case for compounds of formula and 8 in which R" denotes a benzene or naphthalene ring, condensed with the triazole or oxazole ring in the manner indicated by the'valency lines.

Suitable startingmaterials'are for example:

He} CH3 H, CH3

N H {om Q I .i. H, CH3

N- on,

Additionally, the following explanations apply to the preceding formulae:

(1) Terminal phenyl residues may additionally contain further substituents of the alkyl series (especially having 1 to 4 carbon atoms), the halogen series (especially chlorine) or the alkoxy series (especially those having 1 to 4 carbon atoms). (2) Phenyl residues on s-triazine rings may additionally contain methyl groups. (3)

Amongst substitution products of compounds according to Formula 19 there are also to be included the corresponding 6-phenyl-benzoxazoles as well as the analogous l-naphthoxazoles and 2-naphthoxazoles. (4) The symbol H H3C-} denotes that either a hydrogen atom or a methyl group, but in the entire molecule at least one methyl group should be present.

As may be seen from the preceding compilation, all p methylphenyl derivatives of nitrogen-containing: heterocyclics of aromatic character are in principle accessible to the reaction of the invention and, summarizing, the most important categories should again be pointed out, namely such derivatives of pyrrole, pyrazoles, triazoles (1,2,3-, 1,2,4- or 1,3,4), tetrazole, pyridine, pyrimidine, pyrazine, quinazoline quinoxaline, quinolines, n'iazines (1,3,5-, 1,2,4-, 1,2,3-), oxidazoles (1,2,4, 1,3,4) benzoxazoles and naphthoxazoles, (is)oxazoles, imidazoles as well as the corresponding ring systems which are condensed with benzene or naphthalene rings, where these have not already been named.

in which Ar denotes an aromatic residue. In this, either one or both of the components required for the synthesis of the Schiif bases (aldehyde and amine) may contain further substituents, provided the above restrictlon is observed. Since the amine, especially aniline, residue is split 01f during the reaction and is no longer present in the final product, the presence of substituents in this is generally not indicated and is uninteresting. Nevertheless substituents which do not interfere with, or hinder, the reaction, for example chlorine atoms, may be present in this ring also. The benzene residue bonded to the ==HC-- group may for example carry halogen atoms such as bromine or chlorine or alkoxy groups such as methoxy or ethoxy. Preferred interest attaches to Schilf bases of aromatic aldehydes with anilines, that is to say aromatic aldehyde-anils. Such anils for example correspond to the formula in which k and I may be identical or diiferent and denote hydrogen atoms, chlorine atoms or methoxy groups and in which h represents chlorine or, preferably, hydrogen. Adjacent k and I may together also form a group. Another important variant of aromatic anils corresponds to the formula -N=cH-Ar' in which h (as above) represents a hydrogen atom or chlorine and A1" denotes a naphthyl or diphenyl residue. As monoaldehydes suitable for the synthesis of these Schiff bases there may be quoted for example: aldehydes of the benzene series such as benzaldehyde or its halogenated analogues, such as the monochloro-analogues and dichloro-analogues, alkoxybenzaldehydes such as pmethoxy-benzaldehyde, alkylated benzaldehydes, provided these do not contain any p-methyl groups, such as toluyl-aldehyde, xylyl-aldehyde and cumoyl-aldehyde, methylenedioxy-benzaldehyde (piperonal), 4-dimethylamino-benzaldehyde, 4-diethylamino-benzaldehyde, and diphenyl-aldehyde; aldehydes of the naphthalene series such as 0L and fl-naphthaldehyde, and heterocyclic aldehydes such as for example furfurol and thiophenaldehyde.

As suitable amines there may be named, by way of example, the anilines, naphthylamines or, as an aliphatic representative, tert.butylamine.

Compounds of Formula 18 are reacted with the aldehydeanils in the presence of dimethylformamide.

The reaction furthermore requires a strongly basic alkali compound. By the term strongly basic alkali compounds there are to be understood, within the framework of the present invention, such compounds of the alkali metals ((1) main group of the Periodic Table of Elements) including ammonium as have a basic strength of at least about that of lithium, hydroxide. Accordingly, they may be compounds of lithium, sodium, potassium, rubbidium, caesium or ammonium of, for example, the alcoholate, hydroxide, amide, hydride, sulphide or strongly basic ion exchanger types. Potassium compounds of composition m1 2m1 in which m denotes an integer of 1 to 6, such as for example potassium hydroxide or potassium tertiary-butylate, are advantageously used (above all when mild reaction conditions as regards reaction temperature appear to be indicated). In the case of alkali alcoholates and alkali amides (and hydrides) it is here necessary to work in a practically anhydrous medium, whereas in the case of alkali hydroxides water contents of up to 25% (for example contents of water of crystallization) are admissible. In the case of potassium hydroxide a water content of up to about has proved appropriate. As examples of other alkali compounds which may be used there may be quoted sodium methylate, sodium hydroxide, sodium amide, lithium amide, lithium hydroxide, rubidium hyroxide, caesium hdyroxide and the like. Of course it is also possible to work with mixtures of such bases.

In accordance with the preceding explanation, an embodiment of the present invention which is important in practice consists of reacting anils of aldehydes of the benzene and naphthalene series with compounds which correspond to the formula in which formula (a) G, B and D each denote a ring atom of a S-membered or 6-membered ring system of aromatic character, with at least one of the symbols G, B and D representing a nitrogen atom, where D may, instead of nitrogen, also denote the carbon atom and G as well as B may represent carbon, nitrogen, oxygen or sulphur atoms in the arrangement of ring systems which are in themselves known, (b) E represents the ring mem ber supplementation for a S-membered or 6-membercd ring system of aromatic character containing carbon, nitrogen, oxygen or sulphur atoms in the arrangement of ring systems which are in themselves known, and in which (c) the ring formed together with the symbol B may contain further substituents which do not contain any atoms, particularly hydrogen atoms, which are replaceable by alkali, this reaction being carried out in the presence of an alkali compound having a basic strength of at least that of lithium hdyroxide, preferably potassium tertiary-butylate or potassium hydroxide and in dimethylformamide as solvent.

It is appropriate to react the compounds of Formula 18 with the aldehyde-anils in equivalent amounts, so that no component is present in significant excess. As regards the alkali compound, it is advantageous to use at least the equivalent amount, that is to say at least 1 mole, of a compound having, for example, a KO group per mole of aldehyde-anil. When using potassium hydroxide a 4-fold to 8-fold amount is preferably employed.

The reaction of the invention may generally be carried out at temperatures in the range of between about 10 and 150 C. If alcoholates are used as the potassium compound in the reaction, then the application of heat is generally not necessary. The procedure is, for example, that the aldehyde-aniline is added to the mixture of the compound of Formula 18, the solvent and the potassium alcoholate, preferably with stirring and with exclusion of air, at a temperature of between and 30 C., whereupon the reaction takes place of its own accord, with a slight temperature rise. When using potassium hydroxide it is frequently necessary to work at higher temperatures. For example the reaction mixture is slowly warmed to 30- 100 C. and then kept at this temperature for some time, for example V2 to 2 hours. The products may be worked up from the reaction mixture by usual methods which are in themselves known.

The categories of compounds emphasised above as regards their brightener effect possess a more or less pronounced fluorescence in the dissolved or finely divided state. They are suitable for optical brightening of the most diverse organic materials of natural or synthetic origin, or of materials containing such organic substances for which optical brightening is relevant. As such materials there may for example be quoted the following group of organic materials, without the recital which follows in any way being intended to express any limitation in this respect:

(I) Synthetic organic hight molecular materials such as (A) polymerization products based on organic compounds containing at least one polymerizable canboncarbon double bond (homopolymers or copolymers as well as their post-treatment products such as cross-linking products, graft products or degradation products, polymer dilutions and the like), as examples of which there may be quoted: polymers based on m lt-unsaturated carboxylic acids (for example acrylic compounds), olefine hydrocarbons, vinyl and vinylidene compounds, halogenated hydrocarbons, unsaturated aldehydes and ketones, allyl compounds and the like; furthermore polymerization products such as are obtainable by ring opening (for example polyamides of the polycaprolactam type), furthermore formaldehye polymers, or polymers which are obtainable both by polyaddition and by polycondensation such as polythioethers, polyacetals and thioplastics. (B) Polycondensation products or precondensates based on bifunctional or polyfunctional compounds with groups capable of condensation, their homocondensation and cocondensation products as well as post-treatment products (for example saturated and unsaturated, unbranched or branched, polyesters), polyamides, maleate resins, their pre-condensates and products of analogous structure, polycarbonates, silicone resins and others; (G) polyaddition products such as polyurethanes (cross-linked and uncrosslinked) or epoxide resins.

(II) Semi-synthetic organic materials such as for example cellulose esters, nitrocellulose, cellulose ethers, regenerated cellulose or their post-treatment products, and casein plastics.

(III) Natural organic materials with animal or vegetable origin, for example based on cellulose or on proteins such as wool, cotton, silk, leather, wood compositions in a finely divided form, natural resins, and furthermore rubber, guttapercha, balata as well as their p0sttreatment products and modification products.

The organic materials requiring consideration may be present in the most diverse processing states (raw materials, semi-finished goods or finished goods) and states of aggregation. They may thus be present in the form of the most diverse shaped articles, for example as sheets, profiles, injection mouldings, chips, granules, and foams; fllrns, foils, lacquers, strips, coverings, impregnations and coatings or filaments, fibres, flocks, bristles and wires The materials quoted may on the other hand also be present in an unshaped state in the most diverse homogeneous and inhomogeneous forms of distribution and states of aggregation, for example as powders, solutions, emulsions, dispersions, sols, gels, putties, pastes, waxes, adhesives and trowelling compositions and the like.

Fibre materials may for example be present as continuous filaments, staple fibres, flocks, hanks, yarns, threads, fibre fleeces, felts, waddings, flocked structures, woven textile fabrics or laminates, knitted fabrics as well as papers, cardboards or paper compositions and the like.

When used as brighteners, these compounds may be added to the materials quoted either before or during shaping. Thus, for example, they may be added to the moulding composition in the manufacture of films or other moulded articles, or they may be dissolved, dispersed or otherwise finely divided in the spinning composition before spinning. The optical brighteners may also be added to the starting substances, reaction mixtures or intermediate products for the manufacture of fully synthetic or semi-synthetic organic materials, that is to say also before or during the chemical reaction, for example in the case of a polycondensation, a polymerization or a polyaddition.

The new optical brighteners may of course also be employed in all cases where organic materials of the type indicated above are combined with inorganic materials in any form. They are distinguished by exceptionally good heat stability, light fastness and resistance to migration.

The amount of the new optical brightene'rs tobe used,

relative to the material to be optically brightened, may vary within wide limits. A clear and durable effect can already be achieved with very small amounts, in some cases for example with amounts of 0.001 percent by weight. However amounts of up to about 0.5 percent by weight are preferably of interest.

The compounds serving as brighteners may for example also be employed as follows: (a) mixed with dyestuffs or pigments or as an additive to dye baths, printing, etching or reserve pastes. Further also for the posttreatment of dyeing, prints or discharge prints; (b) mixed with so-called carriers, antioxidants, light protection agents, heat stabilizers, chemical bleaching agents or as an additivev tobleaching baths; mixed with crosslinking agents, finishing material such as starch or synthetically produced finishes; (d) in combination with detergents, where the detergent and the brightener may be separately added to the wash baths to be used, or preferably detergents are used which contain the brightener mixed into them; (e) in combination with polymeric carries (polymerization, polycondensation or polyaddition products), in which the brighteners are optionally introduced alongside other substances in a dissolved or dispersed form, (f) as additives to the most diverse industrial products in order to make these more marketable i or to avoid disadvantages in their usability, for example as an additive to glues, adhesives, paints and the like.

The compounds which have been emphasized as optical brighteners may also be used as scintillators for various photographic purposes, such as for electrophotographic reproduction or for super-sensitization.

In the tables which follow later on, symbols have the following significance:

Column I=formula number Column II=structural elements Column III: crude yield in percent Column IV=recrystallization medium, with these being designated by the numbers listed below: 1=water,

2=ethanol, 3=dioxane, 4=dimethylformamide, 5=tetrachlorethylene, 6=chlorobenzeue, 7=o-dichlorobenzene, 8;trichlorobenzene, 9=toluene, l0=n-hexane, 11=xylene.

Column V color of the purified reaction of product, with the latter having been designated by the numbers listed below: 1=colorless, 2=almost colorless, 3 =pale green 4=light green, 5=pale yellow, 6=light yellow, 7=yellow, 8=pale greenish yellow, 9=light greenish yellow, greenish yellow.

Column Vl=melting point (uncorrected) in C.

Column VII=elementary formula and analytical data The starting materials (or the methods for their preparation) to be used forpreparing the compounds in the following examples are known in the are (see Helvetica Chimia Acta, vol. 50, Fasc. 3, pages to 957).

9.1 g. of benzalaniline and 25 g. of potassium hydroxide powder containing about 10% of water are stirred into 300 ml. of dimethylformamide with exclusion of air, during which a red coloration gradually develops. The temperature is raised to C. over the course of 30 minutes, and the mixture stirred for a further 30 minutes at this temperature and then cooled to room temperature. 100 ml. of water and 240 ml. of 10% hydrochloric acid are now successively added dropwise. The precipitated reaction product is washed with a great deal of water and thereafter with ml. of methanol, and is dried. About 15.7 g., corresponding to 90.5% of theory, of the naphthtriazole derivative of formula N@ CH=CH.B.

listed in the following table may be prepared in a similar (upper line calculated, lower line found). 55 manner.

I 1 11,121 111 1V V VI VII 47..--- 91.2 5 8 215-2155 CmsHnONa Q-oom c, 79.55 H, 5.07 N, 11.13 V 19-34 .H, 5.07 N, 11.17

-o1 0, 75.49 H, 4.22 N, 11.00 h c, 75.29 H, 4.04 N, 10.91 49 92.6 7 v 9" -255-250 C90H1N3 c, 85.08 H, 5.00 N, 9.92 7 7 0,849 11, 4.80 N, 10.07 50"... 94.0 5 10 "ins-215.5 018mm,

. ,1 0,8481 H,4.82 N, 10.57 0, 84.45 H, 4.80 N, 10.58

c, 84.61 H, 4.82 N, 10.57 c, 84.85 H, 5.00 N, 10.64

5 TABLECntlnu ed I, 11,133 i v f, V VI l vrr 52--..- 01 v; 66.0 8' 182-182.5 101411101301 53..--. CH3 84,;4 2 4 '5 173.5474 0.1mm:

Q l 0,831.26 H,5.95 11,1010 CH c, 82.88 Bk 5 99 .N. -83 I a... a o--0H, 69.5 5 9 232-288 025111101815 1 C,76.71 H,4.38 N, 10.14 l 0, 76.89 11,4.47 N, 10.11

Example 2 Example 3 5.19 g. of the benztriazole derivative of formula 10-47 of -t e y ')1- y of formula .1

(melting point: 119.5 to 120 C., 4.53 g. of benzalaniline and 12.5 g. of potassium hydroxide powder containing about 10% of water are reacted in 150 ml. of dimethylformamide according to the instructions of Example 13 and are worked up. About 3.7 g., corresponding to 49.8% of theory, of the benztriazole compound of formula are obtained in the form of a light beige powder of melting point 194 to 194.5 C. Two recrystallizations from ethanol with the aid of activated charcoal yield colorless glistening platelets which melt at 196 to 196.5 C. Analysis: C H N (297.34). Calculated: C, 80.71; H, 5.09; N, 14.13. Found: C, 80.74; H, 482;;N, 14.21.

If instead of benzalaniline 6.43 g. of diphenyl- (4)- aldehyde-anil are used, then the compound of the formula is obtained. Yield: 86.7% of theory. Pale greenish yellow glistening small needles from tetrachlorethylene. Melting p 271 to 2 1-5? A aly is: C28H1BN3.(373-44)-.

Calculated: C, 83.62; H, 5.13; N, 11.25. Found: C, 83.57;

. 12.87 g. of diphenyl-(4)-aldehyde-anil and 25 g. of potassium hydroxide powder containing about 10% of Water are stirred into 300 ml. of dimethylformamide with exclusion of air, during which a reddish brown coloration 1 develops. The temperature is raised to C. over the course of 30'minutes, and the-mixture stirred for a further 30 minutes at this temperature and thereafter cooled to room temperature. Now ml. of water and 250 ml. of 10% strength hydrochloric acid are successively added dropwise. The precipitated reaction product is'filtered, Washed with water until neutral and freed of a by-product by further washing with 600 ml. of methanol. After drying about 12.3 g., corresponding to 66.0% of theory, of 4- [benzoxazolyl-(2")]-4'-phenylstilbene of formula 8.4 g., corresponding'to 45.2% of theory, of light yellow glistening platelets of melting point 276 to 276.5 'C. are

obtained. Analysis: C H ON (373.43). Calculated: C,

86.84; H, 5.13; N, 3.75. Found: C, 86.78; H, 5.16; N, 3.83. The 4-[aryloxazolyl-(2")]-4-phenylstilbene derivatives of formula G1OH=CH listed in th e following table may be prepared in a similar H, 5.22; N,11. 10." 'manner 1 11,0. 7 m 1v... v VI v11 7 CarHwON 61 o 80.0 4 8 264-265 0,8668 11,6.34 N,3.26 C,86.85 H,6.11 N,3.29 V N I a 62 o 11.0 5 9 238-238 5 CauHznON C,87.95 H,5.94 N, 2.85 Q CH 0,237.90 H,5.84 N, 2.15

I Q N CH:

TABLE-001111111199 11.9 s 1 915-295 01.119011 A 0,119.19 11,5919 11,9112 0, 86.81 H, 5.40 N, 3.91

191 4 9 zso-ms 0,111,101:

92.1 a. o zoo-19s 091111011 0,119.19 11,5.49 11,9.92 A O, 86.55 H, 5.45 H, 3.82

0, 86.79 H, 5.46 N, 3.92 9 C,86.64 11,1153 N,3.38

99 a a 266-266.& 011119011119 C, 74.44 H, 6.43 N, 4.96 Q 0,1 1.21 H, 0.18 11,4.91

\N Or-NH-(OHfiY-CID T 12,1 1 1 259.5-260 0911901:

, 0,111.91 11,5.90 91,1131 9 r, 0,s1.91-- H, 11.3.29 0 j 9.1a 1 219-2195 0 11 ON Example 4 5.78 g. of na ph$h (1) aldehyde-anil an? 12.5 o; po-

, 1m tassium hydroxi e powder containing 11 out a o waf of wf )1 of ter are stirred into 150 m1. of dimethylformamide with 0am! 9 exclusion of air,during which first 1 Wm e-red and then I w a violet colou develops. The temperature is raised to 60 C. over the course of 30 minutes, and the mixture stirred 0 for a further 30' minutes at this, temperature and thereafter cooled to room temperature. Now 200 m1. of wa- N 7 ter and m1. of 10% strength hydrochloric acid are 5338132178 @1119 20 successively added dropwise. The precipitated r6aQion are obtained in the form of a brownish yellow powder. product is cooledto Cr;-filteredrwashed with water After chromatography 'on'-activated"'alun1inium oxide in .until neutral 21nd freedof ,a. liyepnoducthy'a.urther=w2isl1:= =wwtetmchlqmthylene ..,and,,. reerystallizatidnlirom vdioxaning with a little-methanol. After drying about 7.73: g:, ethanol pale greenish yellqw glistening small'aneedles-tand cdriesponding. 82 of, theory, of the compound of 5 platelets of melting point 165 to..;-16v C. are obtained.

foi-miila Analysis: (3 11 011 (f347.39:)'.--=Qzilculated1-= c, 86.43; H,

4.93; N, 4.03. FoundglQ, 86.54; Pig-4.91; N, 4.08.

The COmEIOUIIdS of the; formula .1 listed in thei following table may he pl epared in a similar manner," A

J; v Y J, 111 IV 70.1... 29.4 2 3 "can on @8632 13,6:25 N, 3.47 Cm 0.86.35 11,0.11 N, 3.56 \T :1" 1 h 7'1..=. o Sameasabove. 90.0 2/3 6 350.5551 CuEuON t 0,111.91 H,5.m N,;-1.a1

/ u C,87.89 11,520 ova .1121

===Ido....== 95.8 2 3 3, 183 18335 1 wounflon 79...: ::::.do.....:..- 72.5 a o 206.5-201 013E110! 0,8733, 11,4.82 11,3.52 C,87.88'- 11,199 N, a.oo 0 I I '1': V 1 1:

81...== o Sameasabove. 61.4 2 3 11 SOS-208.5 onmton TABLEContlnued I I1 I: III IV v VI VII 84...; ::..d0....:.-.": 80.2 9 256-256.5 CuHuON 0,8703 H.482 N, 8.52 0,8788 11,4.83 N,3.58 -O\ 11:, I4=Ha I J1 J1 J4 In 1V V VI vn 85 o H CH: 95.7 5 9 168-1685 CZIHIION 0,8040 11,5.30 N, 3.88 0,8044 H,5.30 N, 3.95

HEM-5:21;.- sameasabovensa. Sam0888b0V6..;;'::::r.' -CH| H 90 2 9 144144.5 CnHnON C,86.40 H,5.30 N,3.88 0,811.88 11,522 N, 9.93

Example 5 ing to 80.6% of theory, of 4-[benzthiazo1yl-(2')]-stilbene 7.24 g. of 1[benzthiaolyl-(2')]-4-methylbenzene of of formula formula (88) 40 6.04 g. of benzalaniline and 16.7 g. of potassium hydroxide powder containing about 10% of water are stirred into 200 ml. of dimethylformamide with exclusion of air, during which a violet coloration develops. The temperature is raised to C. over the course of 30 minutes, and the mixture is stirred for a further 30 minutes at this tempera-ture and then cooled to room temperature. Now m1. of water and ml. of 10% strength hydrochloric acid are succesively added dropwise. The precipitated reaction product is filtered, washed with water until neutral and freed of a by-product by further washing with 300 ml. of methanol. After drying about 8.1 g., correspondare obtained in the form of a light yellow powder which melts at 226 to 228 C. After three recrystallizations from tetrachloroethylene with the aid of Fullers earth pale green very fine crystals of melting point 231 to 231.5 C. are obtained. Analysis: C H NS (313.43). Calculated: C, 80.48; H, 4.82; N, 4.47. Found: C, 80.39; H, 4.98; N, 4.49.

The 4-[benzothiazolyl (2') stilbene derivatives of formula listed in the following table may be prepared in a similiar manner.

11,1:1 III IV V VI VII 90...-.- 82.8 n s 203.5-204 CnHuNSOl -c1 0,7251 .06 N, 4.03 c, 72.00 H, 4. N, 3.95

91-..=-.-= 90.8 5 9 2445-245 CnHuONS -0 on, c, 70.94 H, .99 N, 4.08 0, 70.01 H, 5.01 N, 4.11

92.-.;7. 88.0 7 9 299-300 CnHnNS 0,8328 .92 N, 3.60 c, 83.33 H, 4.79 N, 8.41

93...=== 92.5 2 3 0 145.5-146 CuHnNB c, 82.61 H, 4.71 N, 3,85 0, 82.67 H, 4.70 N, 3.90

94.....2. 80. 5 5 5 249. 15-250 CuHltNS c, 82.01 H, 4.71 3.85 0, 82.38 H, 4.81 N, 3.92

Example 6 5.88 g. of 2-[4'-methylphenyl-(1/)]-5-phenyloxazole of formula 5.44 g. of benzalanih'ne and 12.5 g. of potassium hydroxide powder containing about 10% of water are stirred into 150 ml. of dimethylformamide with exclusion of air, during which a reddish violet coloration develops. The temperature is raised to 60 C. over the course of 30 minutes and the mixture stirred for a further 30 minutes at this temperature and then cooled to room temperature. Now 150 ml. of water and 130 ml. of 10% strength hydrochloric acid are successively added dropwise. The precipitated reaction product is filtered, washed with water until neutral and purified by further washing with 150 ml. of methanol. After drying about 6.2 g., corresponding to 76.8% of theory, of 2-[stilbenyl-(4')]-5- phenyloxazole of formula (90) HCN are obtained in the form of a pale yellow powder which melts at 154.5 to 155.5 C. Two recrystallizations from ethanol, with the aid of-activated charcoal, yield pale green very fine glistening small needles and platelets of melting point 156 ,to 156.5 C. Analysis: CzaHflO N may be used to prepare the Z-[stilbehyl-(4')]oxazole de-;1

rivatives of formula 11 I L, 1., III IV v VI VII 00-.-=.. H 00.0 0 0 204-200 C2|H| ONCl 01 c, 77.20 H, 4.51 N,a.01 0.77.14 H, 4.00 N, 0.00 1

100..==.. H 00.0 0 0 101. 0-1020 CuHnOaN 0 0m 0, 01.00 V H, 0.22 N, 0.00 01.00 H, 0.47 N, 0.00

101....== 0111 E 00. 0 2 2 142-142. 0 I oaHnoN (L 0, 05.40 H, 0.00 N, 2.03 H 0, 00.00 11,010 N,3.98

JJHI

1o2..=== H 00.1 0 0 200-2000 CaHnON 0, 07.10 H, 0.20 N, 0.01 0.07.20 11.0.00 N, 0.27

0, 00.04 H, 0.10 N, 0.70 0, 07.00 H. 0.20 N. 0.70

--:;: 85. 1 5 3 18!. 5-182 CnH ON 0, 07.10 H, 0.00 N, 0.01 0, 07.00 H, 0.02 N, 0.00

106 Same "it: 84.0 5 9 205-207 CnHnONCl 01 0, 00.27 H, 4.00 N, 0.20 0. 00.02 H, 4.00 N, 0.01

107..== 01 Same....:-.:::: 00.0 2 0 171.0-172 CnHnONCh c. 74.37 H. 4.00 N, 2.00 0, 74.40 H, 4.10 N, 0.10 -01 10 same-... 00.0 0 0 102. 0-100 CloHgOgN 0 0m 0, 03.00 H, 0.40 N, 0.20 v 0, 04.01 H, 0.02 N, 0.10

109 Same.-.-=::: 92.5 5. 9 255255.5 CasHuON 0, 20.00 H, .00 N, 2.00 0.00.00 11,040 N, 0.01 110...?: s0m0.-.-=..== 07.1 2 0 0 1000-100 CuHnON 0, 00.17 N, 0.12 1 0, 00.22 H, 0. N, 0.10

' 111": Same.-..:::=: 00.2 a 0 202-2020 CuHnON 0, 00.17 0.10 0.12 e 0, 00.07 H, 0.20 N, 0.00

which are listed in the following-tamer 3,781,278 25 26 Example 7 In a similar manner 1-phenyl-2,5-di-[4'-methylphenyl- 8J3 f h th 1 I ,3 1)]-l,3,4-triazole of Formula 112 5-phenyl-l 2,-di-[4' triazolegog f jg me (1 )1 1 methylphenyl-(l)]-l,3,4-triazole of formula 112 5 (m) M Q Q 9.06 g. of benzalaniline and 25 g. of potassium hydroxide powder containing about of water are stirred into 300 ml. of dimethylformamide with exclusion of air, d 1,2,5.t -i 4'. thy1 h 1.(1') 1,3,4 i l f during which a reddish brown coloration gradually def l velops. The temperature is raised to 60 C. over the (m) cm course of 30 minutes, stirring continued for 30 minutes at this temperature, and the reaction mixture, which is now violet-red, thereafter cooled to room temperature and filtered. Now 100 ml. of water and 250 ml. of 10% strength hydrochloric acid are successively added dropwise. The precipitated reaction product is washed with N a great deal of water and thereafter with 300 ml. of methanol, and is dried. About 11.3 g., corresponding to -Q & 90.0% of theory, of l-phenyl-2,5-di-[stilbenyl- (4')]-1,3,4-

ll triazole of formula may be used to prepare the stilbenyl-l,3,4-triazole derivative of formula are obtained in the form of a practically colorless powder which melts at 333 to 339 C. After three recrystallizations from o-dichlorobenzene with the aid of Fullers earth, colorless very fine felted small needles of melting point 343 to 344 C. are obtained. Analysis: C H N N 501.50 Calculated: c, 86.20; H, 5.43; N, 8.38. Found: Q \CQIECEM' c, 85.91; 11,5.53; N, 8.2-8. ll ll listed in the following table.

1 Q1 Q2 Q8 III IV V VI VII 117".-. H CH=CH I 88.7 7 1 380 CuHuNI c, 88.18 H, 5.40 N, 0.43 c, 87.93 H, 5.40 N, 0.52

Bur-3:31: -C H=CH H 90. 5 6 1 268468.15 CuHflNs C, 86.20 H, 553 N, 8.38 c, 85.91 H, 5.55 N, 8.42

29 30 of theory, of 1-phenyl-3,5-di-[stilbenyl-(4')]-1,2,4-triazole are obtained in the form of a light yellow powder which of formula melts at 307 to 308 C. Three recrystallizations from o- 127) N Q .Li'.

are obtained in the form of a greenish yellow powder. 1 Three recrystallizations from xylene/n-hexane with the aid dichlorobenzene, with the aid of Fullers earth, yield 6.2 of Fullers earth yield about 2.7 g., corresponding to g. corresponding to 45.1% of theory, of light greenish 21.6% of theory, of fine colorless small needles of melting yellow felted small needles of melting point 308 to point 219.5 to 220 C. Analysis: C H N (501.60). Cal- 308.5 C. Analysis: C H N (550.67). Calculated: C, culated: C, 86.20; H, 5.43; N, 8.38. Found: C, 86.17; H, 20 89.42; H, 5.49; N, 5.09. Found: C, 89.35; H, 5.52; N, 5.55; N, 8.29. 4.96.

In a similar manner, l-phenyl-3,5-di-[4" phenylstil- In a similar manner the 1,4,5-triphenyl-2-[4'-methylbenyl-(4') ]-1,2,4-triazole of formula.

is obtained from 12.87 g. of diphenyl-(4)-aldehyde-anil. phenyl-(1')]-imidazole of formula (129) the 2,4,5-tri- Yield: 90.5% of theory. Pale beige-yellow very fine cryphenyl-l-[4'-methylphenyl-(1')]-imidazole of formula stals from dimethylformamide. Melting point: 315 to 317 C. Analysis: C H N (655.78). Calculated: C, (131) 88.18; H, 5.40; N, 6.43. Found: C, 88.29; H, 5.53; N, 6.45.

Example 9 9.66 g. of 1,4,5-triphenyl-2-[4-methyl-phenyl-(1)]- Q- imidazole of formula l Q Q ,5

50 6.46 g. diphenyl-(4)-aldehyde-anil and 12.5 g. of potasand the 4,5-diphenyl-1,2-di[4'-methyl-phenyl-(1')]-imisium hydroxide powder containing about 10% water are dazole of formula stirred into 200 ml. of dimethylformamide with exclusion of air. The temperature is raised to 90 C. over the course (132) of 30 minutes, during which a red coloration gradually QC-N develops. The reaction mixture is stirred for a further Q 30 minutes at to C. and then cooled to room temperature. Now 200 ml. of water and ml. of 10% Q strength hydrochloric acid are successiively added dropwise, with cooling. The precipitated reaction product is 60 filtered off, washed with a great deal of water and then with 400 ml. of methanol and dried. About 8.0 g., corresponding to 58.2% of theory, of 1,4,5-tripheny1-2-[4"- phenyl-stilbeny1-(4')J-imidazole of formula may be used to prepare the stilbenyl-imidazole derivatives of formula.

which are listed in the following table.

in this way has a substantially white appearance than the untreated material.

Example 11 n I U4 Us 111 IV V VI vi: 154... H -on=cn 44.1 5 5 253-2555 0.5mm, I

c, 88.57 H, 5.52 N, 5.90 c, 88.77 H, 5. 51 N, 5.90

135...:===.== H -CE=CH 70.5 2 5 5 2305-2515 mm,

0, 59.25 H 5 N 5.54 c, 89.53 11, 5 51 N, 5.44

1a5..===:=..== -CH=CH H 5 5 2 2255-221 05mm c. 59.42 H, 5.19 N, 5.09 g c, 59.50 H, 5.55 N, 5. 151..=....== -crr=cH -cn=on 55.5 2/5 a 254 05mm,

c, 59.55 H, 5.59 4.55 0 c, 59.51 H, 5. 58 N, 5.99 1as....=====.. -orr=on -orr=on 15.7 n 9 285.5-286 05mm l l o, .55 H, 5.53- 5.54 8 c, 90.74 H 5 N, 4.12 1a9..====.. H -CH=CH 55.4 n 5 274.5-215 0511mm 0, 59.25 H, 5.55 N, 5.54 c, 89.24 H, 5.52 N, 5.23

Example 10 65 Example 12 A polyester fabric (e.g. Dacron) is padded at room temperature (about C.) with an aqueous dispersion containing per litre 2 g. of one of the compounds of Formulae 49, 50 to 54, 56, 57, 59, 61 to 72, 74, 76 to 86, 101, 102 to 111, 117, 121, 130 and 134 to 137 as well as 1 g. of an addition product of about 8 mols of ethylene oxide with 1 mol of para-tert.-octylphenol, and dried at about 100 C. The dry material is subsequently subjected to a heat treatment which lasts from 2 minutes to a few seconds depending on the temperature. The material treated 10,000 parts of polyamide chips prepared in the known manner from hexamethylenediaminadipate are mixed for '12 hours in a tumbling vessel with parts of titanium dioxide (rutile modification) and 2 parts of the com- 7 pounds of Formulae 49, to 54, 56, 57, 59, 61 to 72, 74,

76 to 86, 101, 102 to 111, 117, 121, 130 and 134 to 137. The chips treated in this manner are melted in aboiler--- after it has been swept with superheated steam to displace the atmospheric oxygen-which is heated with oil or diphenyl vapour to a temperature of 300 to 310 C., and

33 stirred for half an hour. The melt is hereupon expressed through a spinneret under nitrogen pressure of atmospheres (gauge), and the thus spun, cooled filament wound onto a spinning bobbin. The resulting threads have an excellent brightening effect.

Example 13 100 g. of polypropylene Fibre-Grade are intimately mixed with 0.02 g. of the compounds of Formulae 49, 50 to 54, 56, 57, 59, 61 to 72, 74, 76 to 86, 101, 102 to 111, 117, 121, 130 and 134 to 137 respectively, and melted, whilst stirring, at a temperature of 280 to 290 C. When the melt is spun through conventional spinnerets and stretched, polypropylene fibres of excellent brightening effect which are fast to light are obtained.

What is claimed is:

1. A compound of the formula in which G denotes hydrogen, an alkyl group having 1 to 4 carbon atoms, a phenyl group, a phenylalkyl group with l to 4 carbon atoms in the alkyl group 'or halogen or a sulphonamido, 6;, represents hydrogen or an alkyl group or may together with an adjacent residue G and the benzene ring on which these G-residues are carried, form a naphthalene ring, g represents hydrogen and J and in which terminal phenyl or naphthyl groups may further contain 1 to 3 alkyl groups, 1 to 2 halogen atoms or an alkoxy group.

2. A compound of the formula wherein G represents 4 (benzoxazolyl-2)-phenyl or 4- (naphthoxazolyl-2)phenyl, wherein the 4-(benzoxabolyl- 2) phenyl is unsubstituted or substituted in position 5 by phenyl, methyl, isopropylphenyl, or tert.butyl, and in position 6 by phenyl or methyl.

3. A compound of the formula Q-Q -Q-4 a).

in which A represents hydrogen, an alkyl group having 1 to 18 carbon atoms or halogen and s denotes an integer of 1 to 3.

4. A compound of the formula in which A, denotes phenyl or phenylalkyl with 1 to 4 carbon atoms in the alkyl moiety.

5. A compound of claim 3 having the formula 6. A compound of claim 3 having the formula CH3 0 om-- References Cited UNITED STATES PATENTS 3,133,916 5/ 1964 Duennenberger et a1.

260-240 CA 3,577,411 5/1971 Miechti et al. 260-240 CA FOREIGN PATENTS 1,378,455 10/ 1964 France 260-240 CA OTHER REFERENCES Netherlands Published Application, page 1 and 1 page of the drawings cited, published May 2, 1967.

Chemical Abstracts, vol. 68, pages 2119 to 2120 (abstract No. 21961h) (1968).

Drefahl et al., Chem. Ber. vol. 93, pages 492 to 497 (1960).

JOHN D. RANDOLPH, Primary Examiner US. Cl. X.R.

96-1R; 106124, 148, 176; 11733.5 T; 252152, 301.2 W, 543; 260-2 S, 46.5, 47 EP, 63 PF, 73 L, 75 N, 77.5 D, 78 R, 78.5 T, 79, 79.7, 80.3 R, 248 CS, 250 A, 251 Q, 283 R, 290 R, 302 R, 304, 307 D, 308 B. 309. 309.2, 310 R, 566 B, 762

- fag UNITED STATES PATENT OFFICE CERTIFICATE OF CORRECTION Patent No. 3,781,278 Dated December 25, 1973 In e r Adolf Emil Siegrist et; a1

It is certified that error appears in the above-identified patent and that said Letters Patent are hereby corrected as shown below:

C olumn 2, line-10, the first formula of the series should read:

, N. I j r ---s I the third formula/of the seriesshould reed:

I l I i lines 50-51, delete "X and Xq deriote pranched alkyl groups, or

one of the substi'tuents".

Column 5, the right-hand portion of formula (l t) should read:

Column 1 1, 1155 3, before "(see", "are" should be art lo the tableunder "11, B formula 51 should reed:

UNITED STATES PATENT OFFICE" CERTIFICATE OF CORRECTION Patent No. 3 7 1 7 Dated Decemb er QS 1973 Inventor) Adolf Emil Siegrist et al -It is certified that error appears in the above-identified patent and that said Letters Patent are hereby corrected as shown below:

Column 15 the left-hend portion of each of formulae (56) and (57) should read:

, Column 16, in the first table under "VII", line, 6, "HR" should be H in the second table under "VII", line 3,- I "0,236.86" should be c,86.83

Column 18, in the table under "VI", line 1, "259.5" should be 295.5 in the table under "VII", line 5 "11,5.86" should be 11,5.85 in the table under "III line 10, 9.48" should be 94$ Column 21, in the first table under "J the lower portion of formula 8 should read:

She second table under "J the righthand portion of formula 5 should read:

line 30, "benzthiaolyl" should be benzthiazolyl J Page 2 of L4- f h A P 3 UNITED STATES PATENT dif lcE CERTIFICATE ECTION Patent No. 3,781,278 Y I I ille 1 e mbere5, 1973 Inventor(s) Adolf Emil s egiiet 'et a1 If: is eerti fied thet error appears in the above-identified patent and that said Lett zers Patent are hereby corrected as shown below;

r Eolumn 22, inthe first table under "III", line 1, "80.2"

should be 80.5

Column 23, line. 1, "(1/)" should be (1' Column 2 1, 1n the table under "v11", line 1, "H1" should be H 1 v 16 I Column 25, in" the table under "Q2", the lower portion of formula 117 should read:

Column 27, in the table under "Q 'the leftha.nd portion of formula 12 r should read:

---g in the table under "Q the left-hand portion of formula 12 should read:

in' the table under "Q formula 125 should read: 

